WASHINGTON, DC, July 6, 2007 (ENS) -
The search for life elsewhere in the solar system and beyond should include research to detect what some scientists call "weird" life, with biochemistry different from that of life on Earth, says a new report from the National Research Council.

The assumption that alien life would have the same biochemical architecture as life on Earth means that scientists have artificially limited the scope of their thinking as to where extraterrestrial life might be found, according to the NASA sponsored report.

"Our investigation made clear that life is possible in forms different than those on Earth," said the chair of the authoring committee John Baross, professor of oceanography at the University of Washington, Seattle.

The authors found that the fundamental requirements for life as we know it - a liquid water biosolvent, carbon-based metabolism, molecular system capable of evolution, and the ability to exchange energy with the environment - are not the only ways to support phenomena recognized as life.

The report emphasizes that "no discovery that we can make in our exploration of the solar system would have greater impact on our view of our position in the cosmos, or be more inspiring, than the discovery of an alien life form, even a primitive one.

At the same time, the report says, "it is clear that nothing would be more tragic in the American exploration of space than to encounter alien life without recognizing it."

"It is critical to know what to look for in the search for life in the solar system," said Baross. "The search so far has focused on Earth-like life because that's all we know, but life that may have originated elsewhere could be unrecognizable compared with life here."

"Advances throughout the last decade in biology and biochemistry show that the basic requirements for life might not be as concrete as we thought," he said.

The report stresses that the future search for alien life should not exclude more research into terrestrial life.

Studies of extreme environments, such as deserts and ocean depths, have determined that life exists anywhere water and a source of energy are found together on Earth.

Baross specializes in the ecology, physiology, and taxonomy of microorganisms from hydrothermal vent environments, and the use of biochemical and molecular methods to detect, quantify, and classify them.

He is part of NASA's astrobiology team, investigating the origin, evolution, distribution and future of life on Earth and beyond.

Baross also researches the ecology of extreme environments and the significance of submarine hydrothermal vent environments for the origin and evolution of life.

A hydrothermal vent is a fissure in a planet's surface that emits heated water. Hydrothermal vents are commonly found near volcanically active places, tectonic plates that are moving apart, ocean basins, and hotspots. The most famous hydrothermal vent system is probably Yellowstone National Park in the United States.

The recent evidence that liquid water-ammonia mixtures may exist in the interior of Saturn's moon Titan suggests the value of another mission to probe Titan, a place the committee considers the solar system's most likely home for weird life.

On Wednesday, NASA announced that for the first time the Cassini spacecraft found cup-like craters filled with hydrocarbons on Saturn's moon Hyperion, the eighth largest of Saturn's nearly 60 known moons.

NASA scientists said this may indicate the widespread presence in our solar system of basic chemicals necessary for life.

A paper in the July 5 issue of the journal "Nature" reports details of Hyperion's surface craters and composition observed during this flyby in 2005, including keys to understanding the moon's origin and evolution over 4.5 billion years.

"Of special interest is the presence on Hyperion of hydrocarbons - combinations of carbon and hydrogen atoms that are found in comets, meteorites, and the dust in our galaxy," said Dale Cruikshank, a planetary scientist at NASA's Ames Research Center, Moffett Field, California, and the paper's lead author.

"These molecules, when embedded in ice and exposed to ultraviolet light, form new molecules of biological significance. This doesn't mean that we have found life," Cruikshank said, "but it is a further indication that the basic chemistry needed for life is widespread in the universe."

Recent evidence indicates that another moon of Saturn, Enceladus, has active water geysers, raising the prospect that habitable environments may exist there.

The report advises that space missions should increase the breadth of their search for life looking for life forms with DNA structures different from those on Earth, and life based on different solvents, such as ammonia, instead of water.

This improved understanding will help scientists to broaden their perspective, seeking life anywhere the conditions necessary for its existence might be met.